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async.c
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1 /*-------------------------------------------------------------------------
2  *
3  * async.c
4  * Asynchronous notification: NOTIFY, LISTEN, UNLISTEN
5  *
6  * Portions Copyright (c) 1996-2024, PostgreSQL Global Development Group
7  * Portions Copyright (c) 1994, Regents of the University of California
8  *
9  * IDENTIFICATION
10  * src/backend/commands/async.c
11  *
12  *-------------------------------------------------------------------------
13  */
14 
15 /*-------------------------------------------------------------------------
16  * Async Notification Model as of 9.0:
17  *
18  * 1. Multiple backends on same machine. Multiple backends listening on
19  * several channels. (Channels are also called "conditions" in other
20  * parts of the code.)
21  *
22  * 2. There is one central queue in disk-based storage (directory pg_notify/),
23  * with actively-used pages mapped into shared memory by the slru.c module.
24  * All notification messages are placed in the queue and later read out
25  * by listening backends.
26  *
27  * There is no central knowledge of which backend listens on which channel;
28  * every backend has its own list of interesting channels.
29  *
30  * Although there is only one queue, notifications are treated as being
31  * database-local; this is done by including the sender's database OID
32  * in each notification message. Listening backends ignore messages
33  * that don't match their database OID. This is important because it
34  * ensures senders and receivers have the same database encoding and won't
35  * misinterpret non-ASCII text in the channel name or payload string.
36  *
37  * Since notifications are not expected to survive database crashes,
38  * we can simply clean out the pg_notify data at any reboot, and there
39  * is no need for WAL support or fsync'ing.
40  *
41  * 3. Every backend that is listening on at least one channel registers by
42  * entering its PID into the array in AsyncQueueControl. It then scans all
43  * incoming notifications in the central queue and first compares the
44  * database OID of the notification with its own database OID and then
45  * compares the notified channel with the list of channels that it listens
46  * to. In case there is a match it delivers the notification event to its
47  * frontend. Non-matching events are simply skipped.
48  *
49  * 4. The NOTIFY statement (routine Async_Notify) stores the notification in
50  * a backend-local list which will not be processed until transaction end.
51  *
52  * Duplicate notifications from the same transaction are sent out as one
53  * notification only. This is done to save work when for example a trigger
54  * on a 2 million row table fires a notification for each row that has been
55  * changed. If the application needs to receive every single notification
56  * that has been sent, it can easily add some unique string into the extra
57  * payload parameter.
58  *
59  * When the transaction is ready to commit, PreCommit_Notify() adds the
60  * pending notifications to the head of the queue. The head pointer of the
61  * queue always points to the next free position and a position is just a
62  * page number and the offset in that page. This is done before marking the
63  * transaction as committed in clog. If we run into problems writing the
64  * notifications, we can still call elog(ERROR, ...) and the transaction
65  * will roll back.
66  *
67  * Once we have put all of the notifications into the queue, we return to
68  * CommitTransaction() which will then do the actual transaction commit.
69  *
70  * After commit we are called another time (AtCommit_Notify()). Here we
71  * make any actual updates to the effective listen state (listenChannels).
72  * Then we signal any backends that may be interested in our messages
73  * (including our own backend, if listening). This is done by
74  * SignalBackends(), which scans the list of listening backends and sends a
75  * PROCSIG_NOTIFY_INTERRUPT signal to every listening backend (we don't
76  * know which backend is listening on which channel so we must signal them
77  * all). We can exclude backends that are already up to date, though, and
78  * we can also exclude backends that are in other databases (unless they
79  * are way behind and should be kicked to make them advance their
80  * pointers).
81  *
82  * Finally, after we are out of the transaction altogether and about to go
83  * idle, we scan the queue for messages that need to be sent to our
84  * frontend (which might be notifies from other backends, or self-notifies
85  * from our own). This step is not part of the CommitTransaction sequence
86  * for two important reasons. First, we could get errors while sending
87  * data to our frontend, and it's really bad for errors to happen in
88  * post-commit cleanup. Second, in cases where a procedure issues commits
89  * within a single frontend command, we don't want to send notifies to our
90  * frontend until the command is done; but notifies to other backends
91  * should go out immediately after each commit.
92  *
93  * 5. Upon receipt of a PROCSIG_NOTIFY_INTERRUPT signal, the signal handler
94  * sets the process's latch, which triggers the event to be processed
95  * immediately if this backend is idle (i.e., it is waiting for a frontend
96  * command and is not within a transaction block. C.f.
97  * ProcessClientReadInterrupt()). Otherwise the handler may only set a
98  * flag, which will cause the processing to occur just before we next go
99  * idle.
100  *
101  * Inbound-notify processing consists of reading all of the notifications
102  * that have arrived since scanning last time. We read every notification
103  * until we reach either a notification from an uncommitted transaction or
104  * the head pointer's position.
105  *
106  * 6. To limit disk space consumption, the tail pointer needs to be advanced
107  * so that old pages can be truncated. This is relatively expensive
108  * (notably, it requires an exclusive lock), so we don't want to do it
109  * often. We make sending backends do this work if they advanced the queue
110  * head into a new page, but only once every QUEUE_CLEANUP_DELAY pages.
111  *
112  * An application that listens on the same channel it notifies will get
113  * NOTIFY messages for its own NOTIFYs. These can be ignored, if not useful,
114  * by comparing be_pid in the NOTIFY message to the application's own backend's
115  * PID. (As of FE/BE protocol 2.0, the backend's PID is provided to the
116  * frontend during startup.) The above design guarantees that notifies from
117  * other backends will never be missed by ignoring self-notifies.
118  *
119  * The amount of shared memory used for notify management (notify_buffers)
120  * can be varied without affecting anything but performance. The maximum
121  * amount of notification data that can be queued at one time is determined
122  * by max_notify_queue_pages GUC.
123  *-------------------------------------------------------------------------
124  */
125 
126 #include "postgres.h"
127 
128 #include <limits.h>
129 #include <unistd.h>
130 #include <signal.h>
131 
132 #include "access/parallel.h"
133 #include "access/slru.h"
134 #include "access/transam.h"
135 #include "access/xact.h"
136 #include "catalog/pg_database.h"
137 #include "commands/async.h"
138 #include "common/hashfn.h"
139 #include "funcapi.h"
140 #include "libpq/libpq.h"
141 #include "libpq/pqformat.h"
142 #include "miscadmin.h"
143 #include "storage/ipc.h"
144 #include "storage/lmgr.h"
145 #include "storage/procsignal.h"
146 #include "tcop/tcopprot.h"
147 #include "utils/builtins.h"
148 #include "utils/guc_hooks.h"
149 #include "utils/memutils.h"
150 #include "utils/ps_status.h"
151 #include "utils/snapmgr.h"
152 #include "utils/timestamp.h"
153 
154 
155 /*
156  * Maximum size of a NOTIFY payload, including terminating NULL. This
157  * must be kept small enough so that a notification message fits on one
158  * SLRU page. The magic fudge factor here is noncritical as long as it's
159  * more than AsyncQueueEntryEmptySize --- we make it significantly bigger
160  * than that, so changes in that data structure won't affect user-visible
161  * restrictions.
162  */
163 #define NOTIFY_PAYLOAD_MAX_LENGTH (BLCKSZ - NAMEDATALEN - 128)
164 
165 /*
166  * Struct representing an entry in the global notify queue
167  *
168  * This struct declaration has the maximal length, but in a real queue entry
169  * the data area is only big enough for the actual channel and payload strings
170  * (each null-terminated). AsyncQueueEntryEmptySize is the minimum possible
171  * entry size, if both channel and payload strings are empty (but note it
172  * doesn't include alignment padding).
173  *
174  * The "length" field should always be rounded up to the next QUEUEALIGN
175  * multiple so that all fields are properly aligned.
176  */
177 typedef struct AsyncQueueEntry
178 {
179  int length; /* total allocated length of entry */
180  Oid dboid; /* sender's database OID */
181  TransactionId xid; /* sender's XID */
182  int32 srcPid; /* sender's PID */
185 
186 /* Currently, no field of AsyncQueueEntry requires more than int alignment */
187 #define QUEUEALIGN(len) INTALIGN(len)
188 
189 #define AsyncQueueEntryEmptySize (offsetof(AsyncQueueEntry, data) + 2)
190 
191 /*
192  * Struct describing a queue position, and assorted macros for working with it
193  */
194 typedef struct QueuePosition
195 {
196  int64 page; /* SLRU page number */
197  int offset; /* byte offset within page */
199 
200 #define QUEUE_POS_PAGE(x) ((x).page)
201 #define QUEUE_POS_OFFSET(x) ((x).offset)
202 
203 #define SET_QUEUE_POS(x,y,z) \
204  do { \
205  (x).page = (y); \
206  (x).offset = (z); \
207  } while (0)
208 
209 #define QUEUE_POS_EQUAL(x,y) \
210  ((x).page == (y).page && (x).offset == (y).offset)
211 
212 #define QUEUE_POS_IS_ZERO(x) \
213  ((x).page == 0 && (x).offset == 0)
214 
215 /* choose logically smaller QueuePosition */
216 #define QUEUE_POS_MIN(x,y) \
217  (asyncQueuePagePrecedes((x).page, (y).page) ? (x) : \
218  (x).page != (y).page ? (y) : \
219  (x).offset < (y).offset ? (x) : (y))
220 
221 /* choose logically larger QueuePosition */
222 #define QUEUE_POS_MAX(x,y) \
223  (asyncQueuePagePrecedes((x).page, (y).page) ? (y) : \
224  (x).page != (y).page ? (x) : \
225  (x).offset > (y).offset ? (x) : (y))
226 
227 /*
228  * Parameter determining how often we try to advance the tail pointer:
229  * we do that after every QUEUE_CLEANUP_DELAY pages of NOTIFY data. This is
230  * also the distance by which a backend in another database needs to be
231  * behind before we'll decide we need to wake it up to advance its pointer.
232  *
233  * Resist the temptation to make this really large. While that would save
234  * work in some places, it would add cost in others. In particular, this
235  * should likely be less than notify_buffers, to ensure that backends
236  * catch up before the pages they'll need to read fall out of SLRU cache.
237  */
238 #define QUEUE_CLEANUP_DELAY 4
239 
240 /*
241  * Struct describing a listening backend's status
242  */
243 typedef struct QueueBackendStatus
244 {
245  int32 pid; /* either a PID or InvalidPid */
246  Oid dboid; /* backend's database OID, or InvalidOid */
247  ProcNumber nextListener; /* id of next listener, or INVALID_PROC_NUMBER */
248  QueuePosition pos; /* backend has read queue up to here */
250 
251 /*
252  * Shared memory state for LISTEN/NOTIFY (excluding its SLRU stuff)
253  *
254  * The AsyncQueueControl structure is protected by the NotifyQueueLock and
255  * NotifyQueueTailLock.
256  *
257  * When holding NotifyQueueLock in SHARED mode, backends may only inspect
258  * their own entries as well as the head and tail pointers. Consequently we
259  * can allow a backend to update its own record while holding only SHARED lock
260  * (since no other backend will inspect it).
261  *
262  * When holding NotifyQueueLock in EXCLUSIVE mode, backends can inspect the
263  * entries of other backends and also change the head pointer. When holding
264  * both NotifyQueueLock and NotifyQueueTailLock in EXCLUSIVE mode, backends
265  * can change the tail pointers.
266  *
267  * SLRU buffer pool is divided in banks and bank wise SLRU lock is used as
268  * the control lock for the pg_notify SLRU buffers.
269  * In order to avoid deadlocks, whenever we need multiple locks, we first get
270  * NotifyQueueTailLock, then NotifyQueueLock, and lastly SLRU bank lock.
271  *
272  * Each backend uses the backend[] array entry with index equal to its
273  * ProcNumber. We rely on this to make SendProcSignal fast.
274  *
275  * The backend[] array entries for actively-listening backends are threaded
276  * together using firstListener and the nextListener links, so that we can
277  * scan them without having to iterate over inactive entries. We keep this
278  * list in order by ProcNumber so that the scan is cache-friendly when there
279  * are many active entries.
280  */
281 typedef struct AsyncQueueControl
282 {
283  QueuePosition head; /* head points to the next free location */
284  QueuePosition tail; /* tail must be <= the queue position of every
285  * listening backend */
286  int64 stopPage; /* oldest unrecycled page; must be <=
287  * tail.page */
288  ProcNumber firstListener; /* id of first listener, or
289  * INVALID_PROC_NUMBER */
290  TimestampTz lastQueueFillWarn; /* time of last queue-full msg */
293 
295 
296 #define QUEUE_HEAD (asyncQueueControl->head)
297 #define QUEUE_TAIL (asyncQueueControl->tail)
298 #define QUEUE_STOP_PAGE (asyncQueueControl->stopPage)
299 #define QUEUE_FIRST_LISTENER (asyncQueueControl->firstListener)
300 #define QUEUE_BACKEND_PID(i) (asyncQueueControl->backend[i].pid)
301 #define QUEUE_BACKEND_DBOID(i) (asyncQueueControl->backend[i].dboid)
302 #define QUEUE_NEXT_LISTENER(i) (asyncQueueControl->backend[i].nextListener)
303 #define QUEUE_BACKEND_POS(i) (asyncQueueControl->backend[i].pos)
304 
305 /*
306  * The SLRU buffer area through which we access the notification queue
307  */
309 
310 #define NotifyCtl (&NotifyCtlData)
311 #define QUEUE_PAGESIZE BLCKSZ
312 
313 #define QUEUE_FULL_WARN_INTERVAL 5000 /* warn at most once every 5s */
314 
315 /*
316  * listenChannels identifies the channels we are actually listening to
317  * (ie, have committed a LISTEN on). It is a simple list of channel names,
318  * allocated in TopMemoryContext.
319  */
320 static List *listenChannels = NIL; /* list of C strings */
321 
322 /*
323  * State for pending LISTEN/UNLISTEN actions consists of an ordered list of
324  * all actions requested in the current transaction. As explained above,
325  * we don't actually change listenChannels until we reach transaction commit.
326  *
327  * The list is kept in CurTransactionContext. In subtransactions, each
328  * subtransaction has its own list in its own CurTransactionContext, but
329  * successful subtransactions attach their lists to their parent's list.
330  * Failed subtransactions simply discard their lists.
331  */
332 typedef enum
333 {
338 
339 typedef struct
340 {
342  char channel[FLEXIBLE_ARRAY_MEMBER]; /* nul-terminated string */
343 } ListenAction;
344 
345 typedef struct ActionList
346 {
347  int nestingLevel; /* current transaction nesting depth */
348  List *actions; /* list of ListenAction structs */
349  struct ActionList *upper; /* details for upper transaction levels */
351 
352 static ActionList *pendingActions = NULL;
353 
354 /*
355  * State for outbound notifies consists of a list of all channels+payloads
356  * NOTIFYed in the current transaction. We do not actually perform a NOTIFY
357  * until and unless the transaction commits. pendingNotifies is NULL if no
358  * NOTIFYs have been done in the current (sub) transaction.
359  *
360  * We discard duplicate notify events issued in the same transaction.
361  * Hence, in addition to the list proper (which we need to track the order
362  * of the events, since we guarantee to deliver them in order), we build a
363  * hash table which we can probe to detect duplicates. Since building the
364  * hash table is somewhat expensive, we do so only once we have at least
365  * MIN_HASHABLE_NOTIFIES events queued in the current (sub) transaction;
366  * before that we just scan the events linearly.
367  *
368  * The list is kept in CurTransactionContext. In subtransactions, each
369  * subtransaction has its own list in its own CurTransactionContext, but
370  * successful subtransactions add their entries to their parent's list.
371  * Failed subtransactions simply discard their lists. Since these lists
372  * are independent, there may be notify events in a subtransaction's list
373  * that duplicate events in some ancestor (sub) transaction; we get rid of
374  * the dups when merging the subtransaction's list into its parent's.
375  *
376  * Note: the action and notify lists do not interact within a transaction.
377  * In particular, if a transaction does NOTIFY and then LISTEN on the same
378  * condition name, it will get a self-notify at commit. This is a bit odd
379  * but is consistent with our historical behavior.
380  */
381 typedef struct Notification
382 {
383  uint16 channel_len; /* length of channel-name string */
384  uint16 payload_len; /* length of payload string */
385  /* null-terminated channel name, then null-terminated payload follow */
388 
389 typedef struct NotificationList
390 {
391  int nestingLevel; /* current transaction nesting depth */
392  List *events; /* list of Notification structs */
393  HTAB *hashtab; /* hash of NotificationHash structs, or NULL */
394  struct NotificationList *upper; /* details for upper transaction levels */
396 
397 #define MIN_HASHABLE_NOTIFIES 16 /* threshold to build hashtab */
398 
400 {
401  Notification *event; /* => the actual Notification struct */
402 };
403 
405 
406 /*
407  * Inbound notifications are initially processed by HandleNotifyInterrupt(),
408  * called from inside a signal handler. That just sets the
409  * notifyInterruptPending flag and sets the process
410  * latch. ProcessNotifyInterrupt() will then be called whenever it's safe to
411  * actually deal with the interrupt.
412  */
413 volatile sig_atomic_t notifyInterruptPending = false;
414 
415 /* True if we've registered an on_shmem_exit cleanup */
416 static bool unlistenExitRegistered = false;
417 
418 /* True if we're currently registered as a listener in asyncQueueControl */
419 static bool amRegisteredListener = false;
420 
421 /* have we advanced to a page that's a multiple of QUEUE_CLEANUP_DELAY? */
422 static bool tryAdvanceTail = false;
423 
424 /* GUC parameters */
425 bool Trace_notify = false;
426 
427 /* For 8 KB pages this gives 8 GB of disk space */
429 
430 /* local function prototypes */
431 static inline int64 asyncQueuePageDiff(int64 p, int64 q);
432 static inline bool asyncQueuePagePrecedes(int64 p, int64 q);
433 static void queue_listen(ListenActionKind action, const char *channel);
434 static void Async_UnlistenOnExit(int code, Datum arg);
435 static void Exec_ListenPreCommit(void);
436 static void Exec_ListenCommit(const char *channel);
437 static void Exec_UnlistenCommit(const char *channel);
438 static void Exec_UnlistenAllCommit(void);
439 static bool IsListeningOn(const char *channel);
440 static void asyncQueueUnregister(void);
441 static bool asyncQueueIsFull(void);
442 static bool asyncQueueAdvance(volatile QueuePosition *position, int entryLength);
444 static ListCell *asyncQueueAddEntries(ListCell *nextNotify);
445 static double asyncQueueUsage(void);
446 static void asyncQueueFillWarning(void);
447 static void SignalBackends(void);
448 static void asyncQueueReadAllNotifications(void);
449 static bool asyncQueueProcessPageEntries(volatile QueuePosition *current,
450  QueuePosition stop,
451  char *page_buffer,
452  Snapshot snapshot);
453 static void asyncQueueAdvanceTail(void);
454 static void ProcessIncomingNotify(bool flush);
455 static bool AsyncExistsPendingNotify(Notification *n);
457 static uint32 notification_hash(const void *key, Size keysize);
458 static int notification_match(const void *key1, const void *key2, Size keysize);
459 static void ClearPendingActionsAndNotifies(void);
460 
461 /*
462  * Compute the difference between two queue page numbers.
463  * Previously this function accounted for a wraparound.
464  */
465 static inline int64
467 {
468  return p - q;
469 }
470 
471 /*
472  * Determines whether p precedes q.
473  * Previously this function accounted for a wraparound.
474  */
475 static inline bool
477 {
478  return p < q;
479 }
480 
481 /*
482  * Report space needed for our shared memory area
483  */
484 Size
486 {
487  Size size;
488 
489  /* This had better match AsyncShmemInit */
491  size = add_size(size, offsetof(AsyncQueueControl, backend));
492 
494 
495  return size;
496 }
497 
498 /*
499  * Initialize our shared memory area
500  */
501 void
503 {
504  bool found;
505  Size size;
506 
507  /*
508  * Create or attach to the AsyncQueueControl structure.
509  */
511  size = add_size(size, offsetof(AsyncQueueControl, backend));
512 
514  ShmemInitStruct("Async Queue Control", size, &found);
515 
516  if (!found)
517  {
518  /* First time through, so initialize it */
519  SET_QUEUE_POS(QUEUE_HEAD, 0, 0);
520  SET_QUEUE_POS(QUEUE_TAIL, 0, 0);
521  QUEUE_STOP_PAGE = 0;
524  for (int i = 0; i < MaxBackends; i++)
525  {
530  }
531  }
532 
533  /*
534  * Set up SLRU management of the pg_notify data. Note that long segment
535  * names are used in order to avoid wraparound.
536  */
537  NotifyCtl->PagePrecedes = asyncQueuePagePrecedes;
538  SimpleLruInit(NotifyCtl, "notify", notify_buffers, 0,
540  SYNC_HANDLER_NONE, true);
541 
542  if (!found)
543  {
544  /*
545  * During start or reboot, clean out the pg_notify directory.
546  */
548  }
549 }
550 
551 
552 /*
553  * pg_notify -
554  * SQL function to send a notification event
555  */
556 Datum
558 {
559  const char *channel;
560  const char *payload;
561 
562  if (PG_ARGISNULL(0))
563  channel = "";
564  else
565  channel = text_to_cstring(PG_GETARG_TEXT_PP(0));
566 
567  if (PG_ARGISNULL(1))
568  payload = "";
569  else
570  payload = text_to_cstring(PG_GETARG_TEXT_PP(1));
571 
572  /* For NOTIFY as a statement, this is checked in ProcessUtility */
574 
575  Async_Notify(channel, payload);
576 
577  PG_RETURN_VOID();
578 }
579 
580 
581 /*
582  * Async_Notify
583  *
584  * This is executed by the SQL notify command.
585  *
586  * Adds the message to the list of pending notifies.
587  * Actual notification happens during transaction commit.
588  * ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
589  */
590 void
591 Async_Notify(const char *channel, const char *payload)
592 {
593  int my_level = GetCurrentTransactionNestLevel();
594  size_t channel_len;
595  size_t payload_len;
596  Notification *n;
597  MemoryContext oldcontext;
598 
599  if (IsParallelWorker())
600  elog(ERROR, "cannot send notifications from a parallel worker");
601 
602  if (Trace_notify)
603  elog(DEBUG1, "Async_Notify(%s)", channel);
604 
605  channel_len = channel ? strlen(channel) : 0;
606  payload_len = payload ? strlen(payload) : 0;
607 
608  /* a channel name must be specified */
609  if (channel_len == 0)
610  ereport(ERROR,
611  (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
612  errmsg("channel name cannot be empty")));
613 
614  /* enforce length limits */
615  if (channel_len >= NAMEDATALEN)
616  ereport(ERROR,
617  (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
618  errmsg("channel name too long")));
619 
620  if (payload_len >= NOTIFY_PAYLOAD_MAX_LENGTH)
621  ereport(ERROR,
622  (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
623  errmsg("payload string too long")));
624 
625  /*
626  * We must construct the Notification entry, even if we end up not using
627  * it, in order to compare it cheaply to existing list entries.
628  *
629  * The notification list needs to live until end of transaction, so store
630  * it in the transaction context.
631  */
633 
634  n = (Notification *) palloc(offsetof(Notification, data) +
635  channel_len + payload_len + 2);
636  n->channel_len = channel_len;
637  n->payload_len = payload_len;
638  strcpy(n->data, channel);
639  if (payload)
640  strcpy(n->data + channel_len + 1, payload);
641  else
642  n->data[channel_len + 1] = '\0';
643 
644  if (pendingNotifies == NULL || my_level > pendingNotifies->nestingLevel)
645  {
646  NotificationList *notifies;
647 
648  /*
649  * First notify event in current (sub)xact. Note that we allocate the
650  * NotificationList in TopTransactionContext; the nestingLevel might
651  * get changed later by AtSubCommit_Notify.
652  */
653  notifies = (NotificationList *)
655  sizeof(NotificationList));
656  notifies->nestingLevel = my_level;
657  notifies->events = list_make1(n);
658  /* We certainly don't need a hashtable yet */
659  notifies->hashtab = NULL;
660  notifies->upper = pendingNotifies;
661  pendingNotifies = notifies;
662  }
663  else
664  {
665  /* Now check for duplicates */
667  {
668  /* It's a dup, so forget it */
669  pfree(n);
670  MemoryContextSwitchTo(oldcontext);
671  return;
672  }
673 
674  /* Append more events to existing list */
676  }
677 
678  MemoryContextSwitchTo(oldcontext);
679 }
680 
681 /*
682  * queue_listen
683  * Common code for listen, unlisten, unlisten all commands.
684  *
685  * Adds the request to the list of pending actions.
686  * Actual update of the listenChannels list happens during transaction
687  * commit.
688  */
689 static void
690 queue_listen(ListenActionKind action, const char *channel)
691 {
692  MemoryContext oldcontext;
693  ListenAction *actrec;
694  int my_level = GetCurrentTransactionNestLevel();
695 
696  /*
697  * Unlike Async_Notify, we don't try to collapse out duplicates. It would
698  * be too complicated to ensure we get the right interactions of
699  * conflicting LISTEN/UNLISTEN/UNLISTEN_ALL, and it's unlikely that there
700  * would be any performance benefit anyway in sane applications.
701  */
703 
704  /* space for terminating null is included in sizeof(ListenAction) */
705  actrec = (ListenAction *) palloc(offsetof(ListenAction, channel) +
706  strlen(channel) + 1);
707  actrec->action = action;
708  strcpy(actrec->channel, channel);
709 
710  if (pendingActions == NULL || my_level > pendingActions->nestingLevel)
711  {
712  ActionList *actions;
713 
714  /*
715  * First action in current sub(xact). Note that we allocate the
716  * ActionList in TopTransactionContext; the nestingLevel might get
717  * changed later by AtSubCommit_Notify.
718  */
719  actions = (ActionList *)
721  actions->nestingLevel = my_level;
722  actions->actions = list_make1(actrec);
723  actions->upper = pendingActions;
724  pendingActions = actions;
725  }
726  else
728 
729  MemoryContextSwitchTo(oldcontext);
730 }
731 
732 /*
733  * Async_Listen
734  *
735  * This is executed by the SQL listen command.
736  */
737 void
738 Async_Listen(const char *channel)
739 {
740  if (Trace_notify)
741  elog(DEBUG1, "Async_Listen(%s,%d)", channel, MyProcPid);
742 
743  queue_listen(LISTEN_LISTEN, channel);
744 }
745 
746 /*
747  * Async_Unlisten
748  *
749  * This is executed by the SQL unlisten command.
750  */
751 void
752 Async_Unlisten(const char *channel)
753 {
754  if (Trace_notify)
755  elog(DEBUG1, "Async_Unlisten(%s,%d)", channel, MyProcPid);
756 
757  /* If we couldn't possibly be listening, no need to queue anything */
758  if (pendingActions == NULL && !unlistenExitRegistered)
759  return;
760 
761  queue_listen(LISTEN_UNLISTEN, channel);
762 }
763 
764 /*
765  * Async_UnlistenAll
766  *
767  * This is invoked by UNLISTEN * command, and also at backend exit.
768  */
769 void
771 {
772  if (Trace_notify)
773  elog(DEBUG1, "Async_UnlistenAll(%d)", MyProcPid);
774 
775  /* If we couldn't possibly be listening, no need to queue anything */
776  if (pendingActions == NULL && !unlistenExitRegistered)
777  return;
778 
780 }
781 
782 /*
783  * SQL function: return a set of the channel names this backend is actively
784  * listening to.
785  *
786  * Note: this coding relies on the fact that the listenChannels list cannot
787  * change within a transaction.
788  */
789 Datum
791 {
792  FuncCallContext *funcctx;
793 
794  /* stuff done only on the first call of the function */
795  if (SRF_IS_FIRSTCALL())
796  {
797  /* create a function context for cross-call persistence */
798  funcctx = SRF_FIRSTCALL_INIT();
799  }
800 
801  /* stuff done on every call of the function */
802  funcctx = SRF_PERCALL_SETUP();
803 
804  if (funcctx->call_cntr < list_length(listenChannels))
805  {
806  char *channel = (char *) list_nth(listenChannels,
807  funcctx->call_cntr);
808 
809  SRF_RETURN_NEXT(funcctx, CStringGetTextDatum(channel));
810  }
811 
812  SRF_RETURN_DONE(funcctx);
813 }
814 
815 /*
816  * Async_UnlistenOnExit
817  *
818  * This is executed at backend exit if we have done any LISTENs in this
819  * backend. It might not be necessary anymore, if the user UNLISTENed
820  * everything, but we don't try to detect that case.
821  */
822 static void
824 {
827 }
828 
829 /*
830  * AtPrepare_Notify
831  *
832  * This is called at the prepare phase of a two-phase
833  * transaction. Save the state for possible commit later.
834  */
835 void
837 {
838  /* It's not allowed to have any pending LISTEN/UNLISTEN/NOTIFY actions */
840  ereport(ERROR,
841  (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
842  errmsg("cannot PREPARE a transaction that has executed LISTEN, UNLISTEN, or NOTIFY")));
843 }
844 
845 /*
846  * PreCommit_Notify
847  *
848  * This is called at transaction commit, before actually committing to
849  * clog.
850  *
851  * If there are pending LISTEN actions, make sure we are listed in the
852  * shared-memory listener array. This must happen before commit to
853  * ensure we don't miss any notifies from transactions that commit
854  * just after ours.
855  *
856  * If there are outbound notify requests in the pendingNotifies list,
857  * add them to the global queue. We do that before commit so that
858  * we can still throw error if we run out of queue space.
859  */
860 void
862 {
863  ListCell *p;
864 
866  return; /* no relevant statements in this xact */
867 
868  if (Trace_notify)
869  elog(DEBUG1, "PreCommit_Notify");
870 
871  /* Preflight for any pending listen/unlisten actions */
872  if (pendingActions != NULL)
873  {
874  foreach(p, pendingActions->actions)
875  {
876  ListenAction *actrec = (ListenAction *) lfirst(p);
877 
878  switch (actrec->action)
879  {
880  case LISTEN_LISTEN:
882  break;
883  case LISTEN_UNLISTEN:
884  /* there is no Exec_UnlistenPreCommit() */
885  break;
886  case LISTEN_UNLISTEN_ALL:
887  /* there is no Exec_UnlistenAllPreCommit() */
888  break;
889  }
890  }
891  }
892 
893  /* Queue any pending notifies (must happen after the above) */
894  if (pendingNotifies)
895  {
896  ListCell *nextNotify;
897 
898  /*
899  * Make sure that we have an XID assigned to the current transaction.
900  * GetCurrentTransactionId is cheap if we already have an XID, but not
901  * so cheap if we don't, and we'd prefer not to do that work while
902  * holding NotifyQueueLock.
903  */
904  (void) GetCurrentTransactionId();
905 
906  /*
907  * Serialize writers by acquiring a special lock that we hold till
908  * after commit. This ensures that queue entries appear in commit
909  * order, and in particular that there are never uncommitted queue
910  * entries ahead of committed ones, so an uncommitted transaction
911  * can't block delivery of deliverable notifications.
912  *
913  * We use a heavyweight lock so that it'll automatically be released
914  * after either commit or abort. This also allows deadlocks to be
915  * detected, though really a deadlock shouldn't be possible here.
916  *
917  * The lock is on "database 0", which is pretty ugly but it doesn't
918  * seem worth inventing a special locktag category just for this.
919  * (Historical note: before PG 9.0, a similar lock on "database 0" was
920  * used by the flatfiles mechanism.)
921  */
922  LockSharedObject(DatabaseRelationId, InvalidOid, 0,
924 
925  /* Now push the notifications into the queue */
926  nextNotify = list_head(pendingNotifies->events);
927  while (nextNotify != NULL)
928  {
929  /*
930  * Add the pending notifications to the queue. We acquire and
931  * release NotifyQueueLock once per page, which might be overkill
932  * but it does allow readers to get in while we're doing this.
933  *
934  * A full queue is very uncommon and should really not happen,
935  * given that we have so much space available in the SLRU pages.
936  * Nevertheless we need to deal with this possibility. Note that
937  * when we get here we are in the process of committing our
938  * transaction, but we have not yet committed to clog, so at this
939  * point in time we can still roll the transaction back.
940  */
941  LWLockAcquire(NotifyQueueLock, LW_EXCLUSIVE);
943  if (asyncQueueIsFull())
944  ereport(ERROR,
945  (errcode(ERRCODE_PROGRAM_LIMIT_EXCEEDED),
946  errmsg("too many notifications in the NOTIFY queue")));
947  nextNotify = asyncQueueAddEntries(nextNotify);
948  LWLockRelease(NotifyQueueLock);
949  }
950 
951  /* Note that we don't clear pendingNotifies; AtCommit_Notify will. */
952  }
953 }
954 
955 /*
956  * AtCommit_Notify
957  *
958  * This is called at transaction commit, after committing to clog.
959  *
960  * Update listenChannels and clear transaction-local state.
961  *
962  * If we issued any notifications in the transaction, send signals to
963  * listening backends (possibly including ourselves) to process them.
964  * Also, if we filled enough queue pages with new notifies, try to
965  * advance the queue tail pointer.
966  */
967 void
969 {
970  ListCell *p;
971 
972  /*
973  * Allow transactions that have not executed LISTEN/UNLISTEN/NOTIFY to
974  * return as soon as possible
975  */
977  return;
978 
979  if (Trace_notify)
980  elog(DEBUG1, "AtCommit_Notify");
981 
982  /* Perform any pending listen/unlisten actions */
983  if (pendingActions != NULL)
984  {
985  foreach(p, pendingActions->actions)
986  {
987  ListenAction *actrec = (ListenAction *) lfirst(p);
988 
989  switch (actrec->action)
990  {
991  case LISTEN_LISTEN:
992  Exec_ListenCommit(actrec->channel);
993  break;
994  case LISTEN_UNLISTEN:
995  Exec_UnlistenCommit(actrec->channel);
996  break;
997  case LISTEN_UNLISTEN_ALL:
999  break;
1000  }
1001  }
1002  }
1003 
1004  /* If no longer listening to anything, get out of listener array */
1007 
1008  /*
1009  * Send signals to listening backends. We need do this only if there are
1010  * pending notifies, which were previously added to the shared queue by
1011  * PreCommit_Notify().
1012  */
1013  if (pendingNotifies != NULL)
1014  SignalBackends();
1015 
1016  /*
1017  * If it's time to try to advance the global tail pointer, do that.
1018  *
1019  * (It might seem odd to do this in the sender, when more than likely the
1020  * listeners won't yet have read the messages we just sent. However,
1021  * there's less contention if only the sender does it, and there is little
1022  * need for urgency in advancing the global tail. So this typically will
1023  * be clearing out messages that were sent some time ago.)
1024  */
1025  if (tryAdvanceTail)
1026  {
1027  tryAdvanceTail = false;
1029  }
1030 
1031  /* And clean up */
1033 }
1034 
1035 /*
1036  * Exec_ListenPreCommit --- subroutine for PreCommit_Notify
1037  *
1038  * This function must make sure we are ready to catch any incoming messages.
1039  */
1040 static void
1042 {
1043  QueuePosition head;
1044  QueuePosition max;
1045  ProcNumber prevListener;
1046 
1047  /*
1048  * Nothing to do if we are already listening to something, nor if we
1049  * already ran this routine in this transaction.
1050  */
1052  return;
1053 
1054  if (Trace_notify)
1055  elog(DEBUG1, "Exec_ListenPreCommit(%d)", MyProcPid);
1056 
1057  /*
1058  * Before registering, make sure we will unlisten before dying. (Note:
1059  * this action does not get undone if we abort later.)
1060  */
1062  {
1064  unlistenExitRegistered = true;
1065  }
1066 
1067  /*
1068  * This is our first LISTEN, so establish our pointer.
1069  *
1070  * We set our pointer to the global tail pointer and then move it forward
1071  * over already-committed notifications. This ensures we cannot miss any
1072  * not-yet-committed notifications. We might get a few more but that
1073  * doesn't hurt.
1074  *
1075  * In some scenarios there might be a lot of committed notifications that
1076  * have not yet been pruned away (because some backend is being lazy about
1077  * reading them). To reduce our startup time, we can look at other
1078  * backends and adopt the maximum "pos" pointer of any backend that's in
1079  * our database; any notifications it's already advanced over are surely
1080  * committed and need not be re-examined by us. (We must consider only
1081  * backends connected to our DB, because others will not have bothered to
1082  * check committed-ness of notifications in our DB.)
1083  *
1084  * We need exclusive lock here so we can look at other backends' entries
1085  * and manipulate the list links.
1086  */
1087  LWLockAcquire(NotifyQueueLock, LW_EXCLUSIVE);
1088  head = QUEUE_HEAD;
1089  max = QUEUE_TAIL;
1090  prevListener = INVALID_PROC_NUMBER;
1092  {
1094  max = QUEUE_POS_MAX(max, QUEUE_BACKEND_POS(i));
1095  /* Also find last listening backend before this one */
1096  if (i < MyProcNumber)
1097  prevListener = i;
1098  }
1102  /* Insert backend into list of listeners at correct position */
1103  if (prevListener != INVALID_PROC_NUMBER)
1104  {
1106  QUEUE_NEXT_LISTENER(prevListener) = MyProcNumber;
1107  }
1108  else
1109  {
1112  }
1113  LWLockRelease(NotifyQueueLock);
1114 
1115  /* Now we are listed in the global array, so remember we're listening */
1116  amRegisteredListener = true;
1117 
1118  /*
1119  * Try to move our pointer forward as far as possible. This will skip
1120  * over already-committed notifications, which we want to do because they
1121  * might be quite stale. Note that we are not yet listening on anything,
1122  * so we won't deliver such notifications to our frontend. Also, although
1123  * our transaction might have executed NOTIFY, those message(s) aren't
1124  * queued yet so we won't skip them here.
1125  */
1126  if (!QUEUE_POS_EQUAL(max, head))
1128 }
1129 
1130 /*
1131  * Exec_ListenCommit --- subroutine for AtCommit_Notify
1132  *
1133  * Add the channel to the list of channels we are listening on.
1134  */
1135 static void
1136 Exec_ListenCommit(const char *channel)
1137 {
1138  MemoryContext oldcontext;
1139 
1140  /* Do nothing if we are already listening on this channel */
1141  if (IsListeningOn(channel))
1142  return;
1143 
1144  /*
1145  * Add the new channel name to listenChannels.
1146  *
1147  * XXX It is theoretically possible to get an out-of-memory failure here,
1148  * which would be bad because we already committed. For the moment it
1149  * doesn't seem worth trying to guard against that, but maybe improve this
1150  * later.
1151  */
1154  MemoryContextSwitchTo(oldcontext);
1155 }
1156 
1157 /*
1158  * Exec_UnlistenCommit --- subroutine for AtCommit_Notify
1159  *
1160  * Remove the specified channel name from listenChannels.
1161  */
1162 static void
1163 Exec_UnlistenCommit(const char *channel)
1164 {
1165  ListCell *q;
1166 
1167  if (Trace_notify)
1168  elog(DEBUG1, "Exec_UnlistenCommit(%s,%d)", channel, MyProcPid);
1169 
1170  foreach(q, listenChannels)
1171  {
1172  char *lchan = (char *) lfirst(q);
1173 
1174  if (strcmp(lchan, channel) == 0)
1175  {
1177  pfree(lchan);
1178  break;
1179  }
1180  }
1181 
1182  /*
1183  * We do not complain about unlistening something not being listened;
1184  * should we?
1185  */
1186 }
1187 
1188 /*
1189  * Exec_UnlistenAllCommit --- subroutine for AtCommit_Notify
1190  *
1191  * Unlisten on all channels for this backend.
1192  */
1193 static void
1195 {
1196  if (Trace_notify)
1197  elog(DEBUG1, "Exec_UnlistenAllCommit(%d)", MyProcPid);
1198 
1200  listenChannels = NIL;
1201 }
1202 
1203 /*
1204  * Test whether we are actively listening on the given channel name.
1205  *
1206  * Note: this function is executed for every notification found in the queue.
1207  * Perhaps it is worth further optimization, eg convert the list to a sorted
1208  * array so we can binary-search it. In practice the list is likely to be
1209  * fairly short, though.
1210  */
1211 static bool
1212 IsListeningOn(const char *channel)
1213 {
1214  ListCell *p;
1215 
1216  foreach(p, listenChannels)
1217  {
1218  char *lchan = (char *) lfirst(p);
1219 
1220  if (strcmp(lchan, channel) == 0)
1221  return true;
1222  }
1223  return false;
1224 }
1225 
1226 /*
1227  * Remove our entry from the listeners array when we are no longer listening
1228  * on any channel. NB: must not fail if we're already not listening.
1229  */
1230 static void
1232 {
1233  Assert(listenChannels == NIL); /* else caller error */
1234 
1235  if (!amRegisteredListener) /* nothing to do */
1236  return;
1237 
1238  /*
1239  * Need exclusive lock here to manipulate list links.
1240  */
1241  LWLockAcquire(NotifyQueueLock, LW_EXCLUSIVE);
1242  /* Mark our entry as invalid */
1245  /* and remove it from the list */
1248  else
1249  {
1251  {
1253  {
1255  break;
1256  }
1257  }
1258  }
1260  LWLockRelease(NotifyQueueLock);
1261 
1262  /* mark ourselves as no longer listed in the global array */
1263  amRegisteredListener = false;
1264 }
1265 
1266 /*
1267  * Test whether there is room to insert more notification messages.
1268  *
1269  * Caller must hold at least shared NotifyQueueLock.
1270  */
1271 static bool
1273 {
1274  int64 headPage = QUEUE_POS_PAGE(QUEUE_HEAD);
1275  int64 tailPage = QUEUE_POS_PAGE(QUEUE_TAIL);
1276  int64 occupied = headPage - tailPage;
1277 
1278  return occupied >= max_notify_queue_pages;
1279 }
1280 
1281 /*
1282  * Advance the QueuePosition to the next entry, assuming that the current
1283  * entry is of length entryLength. If we jump to a new page the function
1284  * returns true, else false.
1285  */
1286 static bool
1287 asyncQueueAdvance(volatile QueuePosition *position, int entryLength)
1288 {
1289  int64 pageno = QUEUE_POS_PAGE(*position);
1290  int offset = QUEUE_POS_OFFSET(*position);
1291  bool pageJump = false;
1292 
1293  /*
1294  * Move to the next writing position: First jump over what we have just
1295  * written or read.
1296  */
1297  offset += entryLength;
1298  Assert(offset <= QUEUE_PAGESIZE);
1299 
1300  /*
1301  * In a second step check if another entry can possibly be written to the
1302  * page. If so, stay here, we have reached the next position. If not, then
1303  * we need to move on to the next page.
1304  */
1306  {
1307  pageno++;
1308  offset = 0;
1309  pageJump = true;
1310  }
1311 
1312  SET_QUEUE_POS(*position, pageno, offset);
1313  return pageJump;
1314 }
1315 
1316 /*
1317  * Fill the AsyncQueueEntry at *qe with an outbound notification message.
1318  */
1319 static void
1321 {
1322  size_t channellen = n->channel_len;
1323  size_t payloadlen = n->payload_len;
1324  int entryLength;
1325 
1326  Assert(channellen < NAMEDATALEN);
1327  Assert(payloadlen < NOTIFY_PAYLOAD_MAX_LENGTH);
1328 
1329  /* The terminators are already included in AsyncQueueEntryEmptySize */
1330  entryLength = AsyncQueueEntryEmptySize + payloadlen + channellen;
1331  entryLength = QUEUEALIGN(entryLength);
1332  qe->length = entryLength;
1333  qe->dboid = MyDatabaseId;
1334  qe->xid = GetCurrentTransactionId();
1335  qe->srcPid = MyProcPid;
1336  memcpy(qe->data, n->data, channellen + payloadlen + 2);
1337 }
1338 
1339 /*
1340  * Add pending notifications to the queue.
1341  *
1342  * We go page by page here, i.e. we stop once we have to go to a new page but
1343  * we will be called again and then fill that next page. If an entry does not
1344  * fit into the current page, we write a dummy entry with an InvalidOid as the
1345  * database OID in order to fill the page. So every page is always used up to
1346  * the last byte which simplifies reading the page later.
1347  *
1348  * We are passed the list cell (in pendingNotifies->events) containing the next
1349  * notification to write and return the first still-unwritten cell back.
1350  * Eventually we will return NULL indicating all is done.
1351  *
1352  * We are holding NotifyQueueLock already from the caller and grab
1353  * page specific SLRU bank lock locally in this function.
1354  */
1355 static ListCell *
1357 {
1358  AsyncQueueEntry qe;
1359  QueuePosition queue_head;
1360  int64 pageno;
1361  int offset;
1362  int slotno;
1363  LWLock *prevlock;
1364 
1365  /*
1366  * We work with a local copy of QUEUE_HEAD, which we write back to shared
1367  * memory upon exiting. The reason for this is that if we have to advance
1368  * to a new page, SimpleLruZeroPage might fail (out of disk space, for
1369  * instance), and we must not advance QUEUE_HEAD if it does. (Otherwise,
1370  * subsequent insertions would try to put entries into a page that slru.c
1371  * thinks doesn't exist yet.) So, use a local position variable. Note
1372  * that if we do fail, any already-inserted queue entries are forgotten;
1373  * this is okay, since they'd be useless anyway after our transaction
1374  * rolls back.
1375  */
1376  queue_head = QUEUE_HEAD;
1377 
1378  /*
1379  * If this is the first write since the postmaster started, we need to
1380  * initialize the first page of the async SLRU. Otherwise, the current
1381  * page should be initialized already, so just fetch it.
1382  */
1383  pageno = QUEUE_POS_PAGE(queue_head);
1384  prevlock = SimpleLruGetBankLock(NotifyCtl, pageno);
1385 
1386  /* We hold both NotifyQueueLock and SLRU bank lock during this operation */
1387  LWLockAcquire(prevlock, LW_EXCLUSIVE);
1388 
1389  if (QUEUE_POS_IS_ZERO(queue_head))
1390  slotno = SimpleLruZeroPage(NotifyCtl, pageno);
1391  else
1392  slotno = SimpleLruReadPage(NotifyCtl, pageno, true,
1394 
1395  /* Note we mark the page dirty before writing in it */
1396  NotifyCtl->shared->page_dirty[slotno] = true;
1397 
1398  while (nextNotify != NULL)
1399  {
1400  Notification *n = (Notification *) lfirst(nextNotify);
1401 
1402  /* Construct a valid queue entry in local variable qe */
1404 
1405  offset = QUEUE_POS_OFFSET(queue_head);
1406 
1407  /* Check whether the entry really fits on the current page */
1408  if (offset + qe.length <= QUEUE_PAGESIZE)
1409  {
1410  /* OK, so advance nextNotify past this item */
1411  nextNotify = lnext(pendingNotifies->events, nextNotify);
1412  }
1413  else
1414  {
1415  /*
1416  * Write a dummy entry to fill up the page. Actually readers will
1417  * only check dboid and since it won't match any reader's database
1418  * OID, they will ignore this entry and move on.
1419  */
1420  qe.length = QUEUE_PAGESIZE - offset;
1421  qe.dboid = InvalidOid;
1422  qe.data[0] = '\0'; /* empty channel */
1423  qe.data[1] = '\0'; /* empty payload */
1424  }
1425 
1426  /* Now copy qe into the shared buffer page */
1427  memcpy(NotifyCtl->shared->page_buffer[slotno] + offset,
1428  &qe,
1429  qe.length);
1430 
1431  /* Advance queue_head appropriately, and detect if page is full */
1432  if (asyncQueueAdvance(&(queue_head), qe.length))
1433  {
1434  LWLock *lock;
1435 
1436  pageno = QUEUE_POS_PAGE(queue_head);
1437  lock = SimpleLruGetBankLock(NotifyCtl, pageno);
1438  if (lock != prevlock)
1439  {
1440  LWLockRelease(prevlock);
1441  LWLockAcquire(lock, LW_EXCLUSIVE);
1442  prevlock = lock;
1443  }
1444 
1445  /*
1446  * Page is full, so we're done here, but first fill the next page
1447  * with zeroes. The reason to do this is to ensure that slru.c's
1448  * idea of the head page is always the same as ours, which avoids
1449  * boundary problems in SimpleLruTruncate. The test in
1450  * asyncQueueIsFull() ensured that there is room to create this
1451  * page without overrunning the queue.
1452  */
1453  slotno = SimpleLruZeroPage(NotifyCtl, QUEUE_POS_PAGE(queue_head));
1454 
1455  /*
1456  * If the new page address is a multiple of QUEUE_CLEANUP_DELAY,
1457  * set flag to remember that we should try to advance the tail
1458  * pointer (we don't want to actually do that right here).
1459  */
1460  if (QUEUE_POS_PAGE(queue_head) % QUEUE_CLEANUP_DELAY == 0)
1461  tryAdvanceTail = true;
1462 
1463  /* And exit the loop */
1464  break;
1465  }
1466  }
1467 
1468  /* Success, so update the global QUEUE_HEAD */
1469  QUEUE_HEAD = queue_head;
1470 
1471  LWLockRelease(prevlock);
1472 
1473  return nextNotify;
1474 }
1475 
1476 /*
1477  * SQL function to return the fraction of the notification queue currently
1478  * occupied.
1479  */
1480 Datum
1482 {
1483  double usage;
1484 
1485  /* Advance the queue tail so we don't report a too-large result */
1487 
1488  LWLockAcquire(NotifyQueueLock, LW_SHARED);
1489  usage = asyncQueueUsage();
1490  LWLockRelease(NotifyQueueLock);
1491 
1493 }
1494 
1495 /*
1496  * Return the fraction of the queue that is currently occupied.
1497  *
1498  * The caller must hold NotifyQueueLock in (at least) shared mode.
1499  *
1500  * Note: we measure the distance to the logical tail page, not the physical
1501  * tail page. In some sense that's wrong, but the relative position of the
1502  * physical tail is affected by details such as SLRU segment boundaries,
1503  * so that a result based on that is unpleasantly unstable.
1504  */
1505 static double
1507 {
1508  int64 headPage = QUEUE_POS_PAGE(QUEUE_HEAD);
1509  int64 tailPage = QUEUE_POS_PAGE(QUEUE_TAIL);
1510  int64 occupied = headPage - tailPage;
1511 
1512  if (occupied == 0)
1513  return (double) 0; /* fast exit for common case */
1514 
1515  return (double) occupied / (double) max_notify_queue_pages;
1516 }
1517 
1518 /*
1519  * Check whether the queue is at least half full, and emit a warning if so.
1520  *
1521  * This is unlikely given the size of the queue, but possible.
1522  * The warnings show up at most once every QUEUE_FULL_WARN_INTERVAL.
1523  *
1524  * Caller must hold exclusive NotifyQueueLock.
1525  */
1526 static void
1528 {
1529  double fillDegree;
1530  TimestampTz t;
1531 
1532  fillDegree = asyncQueueUsage();
1533  if (fillDegree < 0.5)
1534  return;
1535 
1536  t = GetCurrentTimestamp();
1537 
1540  {
1541  QueuePosition min = QUEUE_HEAD;
1542  int32 minPid = InvalidPid;
1543 
1545  {
1547  min = QUEUE_POS_MIN(min, QUEUE_BACKEND_POS(i));
1548  if (QUEUE_POS_EQUAL(min, QUEUE_BACKEND_POS(i)))
1549  minPid = QUEUE_BACKEND_PID(i);
1550  }
1551 
1552  ereport(WARNING,
1553  (errmsg("NOTIFY queue is %.0f%% full", fillDegree * 100),
1554  (minPid != InvalidPid ?
1555  errdetail("The server process with PID %d is among those with the oldest transactions.", minPid)
1556  : 0),
1557  (minPid != InvalidPid ?
1558  errhint("The NOTIFY queue cannot be emptied until that process ends its current transaction.")
1559  : 0)));
1560 
1562  }
1563 }
1564 
1565 /*
1566  * Send signals to listening backends.
1567  *
1568  * Normally we signal only backends in our own database, since only those
1569  * backends could be interested in notifies we send. However, if there's
1570  * notify traffic in our database but no traffic in another database that
1571  * does have listener(s), those listeners will fall further and further
1572  * behind. Waken them anyway if they're far enough behind, so that they'll
1573  * advance their queue position pointers, allowing the global tail to advance.
1574  *
1575  * Since we know the ProcNumber and the Pid the signaling is quite cheap.
1576  *
1577  * This is called during CommitTransaction(), so it's important for it
1578  * to have very low probability of failure.
1579  */
1580 static void
1582 {
1583  int32 *pids;
1584  ProcNumber *procnos;
1585  int count;
1586 
1587  /*
1588  * Identify backends that we need to signal. We don't want to send
1589  * signals while holding the NotifyQueueLock, so this loop just builds a
1590  * list of target PIDs.
1591  *
1592  * XXX in principle these pallocs could fail, which would be bad. Maybe
1593  * preallocate the arrays? They're not that large, though.
1594  */
1595  pids = (int32 *) palloc(MaxBackends * sizeof(int32));
1596  procnos = (ProcNumber *) palloc(MaxBackends * sizeof(ProcNumber));
1597  count = 0;
1598 
1599  LWLockAcquire(NotifyQueueLock, LW_EXCLUSIVE);
1601  {
1602  int32 pid = QUEUE_BACKEND_PID(i);
1603  QueuePosition pos;
1604 
1605  Assert(pid != InvalidPid);
1606  pos = QUEUE_BACKEND_POS(i);
1608  {
1609  /*
1610  * Always signal listeners in our own database, unless they're
1611  * already caught up (unlikely, but possible).
1612  */
1613  if (QUEUE_POS_EQUAL(pos, QUEUE_HEAD))
1614  continue;
1615  }
1616  else
1617  {
1618  /*
1619  * Listeners in other databases should be signaled only if they
1620  * are far behind.
1621  */
1624  continue;
1625  }
1626  /* OK, need to signal this one */
1627  pids[count] = pid;
1628  procnos[count] = i;
1629  count++;
1630  }
1631  LWLockRelease(NotifyQueueLock);
1632 
1633  /* Now send signals */
1634  for (int i = 0; i < count; i++)
1635  {
1636  int32 pid = pids[i];
1637 
1638  /*
1639  * If we are signaling our own process, no need to involve the kernel;
1640  * just set the flag directly.
1641  */
1642  if (pid == MyProcPid)
1643  {
1644  notifyInterruptPending = true;
1645  continue;
1646  }
1647 
1648  /*
1649  * Note: assuming things aren't broken, a signal failure here could
1650  * only occur if the target backend exited since we released
1651  * NotifyQueueLock; which is unlikely but certainly possible. So we
1652  * just log a low-level debug message if it happens.
1653  */
1654  if (SendProcSignal(pid, PROCSIG_NOTIFY_INTERRUPT, procnos[i]) < 0)
1655  elog(DEBUG3, "could not signal backend with PID %d: %m", pid);
1656  }
1657 
1658  pfree(pids);
1659  pfree(procnos);
1660 }
1661 
1662 /*
1663  * AtAbort_Notify
1664  *
1665  * This is called at transaction abort.
1666  *
1667  * Gets rid of pending actions and outbound notifies that we would have
1668  * executed if the transaction got committed.
1669  */
1670 void
1672 {
1673  /*
1674  * If we LISTEN but then roll back the transaction after PreCommit_Notify,
1675  * we have registered as a listener but have not made any entry in
1676  * listenChannels. In that case, deregister again.
1677  */
1680 
1681  /* And clean up */
1683 }
1684 
1685 /*
1686  * AtSubCommit_Notify() --- Take care of subtransaction commit.
1687  *
1688  * Reassign all items in the pending lists to the parent transaction.
1689  */
1690 void
1692 {
1693  int my_level = GetCurrentTransactionNestLevel();
1694 
1695  /* If there are actions at our nesting level, we must reparent them. */
1696  if (pendingActions != NULL &&
1697  pendingActions->nestingLevel >= my_level)
1698  {
1699  if (pendingActions->upper == NULL ||
1700  pendingActions->upper->nestingLevel < my_level - 1)
1701  {
1702  /* nothing to merge; give the whole thing to the parent */
1704  }
1705  else
1706  {
1707  ActionList *childPendingActions = pendingActions;
1708 
1710 
1711  /*
1712  * Mustn't try to eliminate duplicates here --- see queue_listen()
1713  */
1716  childPendingActions->actions);
1717  pfree(childPendingActions);
1718  }
1719  }
1720 
1721  /* If there are notifies at our nesting level, we must reparent them. */
1722  if (pendingNotifies != NULL &&
1723  pendingNotifies->nestingLevel >= my_level)
1724  {
1725  Assert(pendingNotifies->nestingLevel == my_level);
1726 
1727  if (pendingNotifies->upper == NULL ||
1728  pendingNotifies->upper->nestingLevel < my_level - 1)
1729  {
1730  /* nothing to merge; give the whole thing to the parent */
1732  }
1733  else
1734  {
1735  /*
1736  * Formerly, we didn't bother to eliminate duplicates here, but
1737  * now we must, else we fall foul of "Assert(!found)", either here
1738  * or during a later attempt to build the parent-level hashtable.
1739  */
1740  NotificationList *childPendingNotifies = pendingNotifies;
1741  ListCell *l;
1742 
1744  /* Insert all the subxact's events into parent, except for dups */
1745  foreach(l, childPendingNotifies->events)
1746  {
1747  Notification *childn = (Notification *) lfirst(l);
1748 
1749  if (!AsyncExistsPendingNotify(childn))
1750  AddEventToPendingNotifies(childn);
1751  }
1752  pfree(childPendingNotifies);
1753  }
1754  }
1755 }
1756 
1757 /*
1758  * AtSubAbort_Notify() --- Take care of subtransaction abort.
1759  */
1760 void
1762 {
1763  int my_level = GetCurrentTransactionNestLevel();
1764 
1765  /*
1766  * All we have to do is pop the stack --- the actions/notifies made in
1767  * this subxact are no longer interesting, and the space will be freed
1768  * when CurTransactionContext is recycled. We still have to free the
1769  * ActionList and NotificationList objects themselves, though, because
1770  * those are allocated in TopTransactionContext.
1771  *
1772  * Note that there might be no entries at all, or no entries for the
1773  * current subtransaction level, either because none were ever created, or
1774  * because we reentered this routine due to trouble during subxact abort.
1775  */
1776  while (pendingActions != NULL &&
1777  pendingActions->nestingLevel >= my_level)
1778  {
1779  ActionList *childPendingActions = pendingActions;
1780 
1782  pfree(childPendingActions);
1783  }
1784 
1785  while (pendingNotifies != NULL &&
1786  pendingNotifies->nestingLevel >= my_level)
1787  {
1788  NotificationList *childPendingNotifies = pendingNotifies;
1789 
1791  pfree(childPendingNotifies);
1792  }
1793 }
1794 
1795 /*
1796  * HandleNotifyInterrupt
1797  *
1798  * Signal handler portion of interrupt handling. Let the backend know
1799  * that there's a pending notify interrupt. If we're currently reading
1800  * from the client, this will interrupt the read and
1801  * ProcessClientReadInterrupt() will call ProcessNotifyInterrupt().
1802  */
1803 void
1805 {
1806  /*
1807  * Note: this is called by a SIGNAL HANDLER. You must be very wary what
1808  * you do here.
1809  */
1810 
1811  /* signal that work needs to be done */
1812  notifyInterruptPending = true;
1813 
1814  /* make sure the event is processed in due course */
1815  SetLatch(MyLatch);
1816 }
1817 
1818 /*
1819  * ProcessNotifyInterrupt
1820  *
1821  * This is called if we see notifyInterruptPending set, just before
1822  * transmitting ReadyForQuery at the end of a frontend command, and
1823  * also if a notify signal occurs while reading from the frontend.
1824  * HandleNotifyInterrupt() will cause the read to be interrupted
1825  * via the process's latch, and this routine will get called.
1826  * If we are truly idle (ie, *not* inside a transaction block),
1827  * process the incoming notifies.
1828  *
1829  * If "flush" is true, force any frontend messages out immediately.
1830  * This can be false when being called at the end of a frontend command,
1831  * since we'll flush after sending ReadyForQuery.
1832  */
1833 void
1835 {
1837  return; /* not really idle */
1838 
1839  /* Loop in case another signal arrives while sending messages */
1840  while (notifyInterruptPending)
1841  ProcessIncomingNotify(flush);
1842 }
1843 
1844 
1845 /*
1846  * Read all pending notifications from the queue, and deliver appropriate
1847  * ones to my frontend. Stop when we reach queue head or an uncommitted
1848  * notification.
1849  */
1850 static void
1852 {
1853  volatile QueuePosition pos;
1854  QueuePosition head;
1855  Snapshot snapshot;
1856 
1857  /* page_buffer must be adequately aligned, so use a union */
1858  union
1859  {
1860  char buf[QUEUE_PAGESIZE];
1861  AsyncQueueEntry align;
1862  } page_buffer;
1863 
1864  /* Fetch current state */
1865  LWLockAcquire(NotifyQueueLock, LW_SHARED);
1866  /* Assert checks that we have a valid state entry */
1869  head = QUEUE_HEAD;
1870  LWLockRelease(NotifyQueueLock);
1871 
1872  if (QUEUE_POS_EQUAL(pos, head))
1873  {
1874  /* Nothing to do, we have read all notifications already. */
1875  return;
1876  }
1877 
1878  /*----------
1879  * Get snapshot we'll use to decide which xacts are still in progress.
1880  * This is trickier than it might seem, because of race conditions.
1881  * Consider the following example:
1882  *
1883  * Backend 1: Backend 2:
1884  *
1885  * transaction starts
1886  * UPDATE foo SET ...;
1887  * NOTIFY foo;
1888  * commit starts
1889  * queue the notify message
1890  * transaction starts
1891  * LISTEN foo; -- first LISTEN in session
1892  * SELECT * FROM foo WHERE ...;
1893  * commit to clog
1894  * commit starts
1895  * add backend 2 to array of listeners
1896  * advance to queue head (this code)
1897  * commit to clog
1898  *
1899  * Transaction 2's SELECT has not seen the UPDATE's effects, since that
1900  * wasn't committed yet. Ideally we'd ensure that client 2 would
1901  * eventually get transaction 1's notify message, but there's no way
1902  * to do that; until we're in the listener array, there's no guarantee
1903  * that the notify message doesn't get removed from the queue.
1904  *
1905  * Therefore the coding technique transaction 2 is using is unsafe:
1906  * applications must commit a LISTEN before inspecting database state,
1907  * if they want to ensure they will see notifications about subsequent
1908  * changes to that state.
1909  *
1910  * What we do guarantee is that we'll see all notifications from
1911  * transactions committing after the snapshot we take here.
1912  * Exec_ListenPreCommit has already added us to the listener array,
1913  * so no not-yet-committed messages can be removed from the queue
1914  * before we see them.
1915  *----------
1916  */
1917  snapshot = RegisterSnapshot(GetLatestSnapshot());
1918 
1919  /*
1920  * It is possible that we fail while trying to send a message to our
1921  * frontend (for example, because of encoding conversion failure). If
1922  * that happens it is critical that we not try to send the same message
1923  * over and over again. Therefore, we place a PG_TRY block here that will
1924  * forcibly advance our queue position before we lose control to an error.
1925  * (We could alternatively retake NotifyQueueLock and move the position
1926  * before handling each individual message, but that seems like too much
1927  * lock traffic.)
1928  */
1929  PG_TRY();
1930  {
1931  bool reachedStop;
1932 
1933  do
1934  {
1935  int64 curpage = QUEUE_POS_PAGE(pos);
1936  int curoffset = QUEUE_POS_OFFSET(pos);
1937  int slotno;
1938  int copysize;
1939 
1940  /*
1941  * We copy the data from SLRU into a local buffer, so as to avoid
1942  * holding the SLRU lock while we are examining the entries and
1943  * possibly transmitting them to our frontend. Copy only the part
1944  * of the page we will actually inspect.
1945  */
1946  slotno = SimpleLruReadPage_ReadOnly(NotifyCtl, curpage,
1948  if (curpage == QUEUE_POS_PAGE(head))
1949  {
1950  /* we only want to read as far as head */
1951  copysize = QUEUE_POS_OFFSET(head) - curoffset;
1952  if (copysize < 0)
1953  copysize = 0; /* just for safety */
1954  }
1955  else
1956  {
1957  /* fetch all the rest of the page */
1958  copysize = QUEUE_PAGESIZE - curoffset;
1959  }
1960  memcpy(page_buffer.buf + curoffset,
1961  NotifyCtl->shared->page_buffer[slotno] + curoffset,
1962  copysize);
1963  /* Release lock that we got from SimpleLruReadPage_ReadOnly() */
1965 
1966  /*
1967  * Process messages up to the stop position, end of page, or an
1968  * uncommitted message.
1969  *
1970  * Our stop position is what we found to be the head's position
1971  * when we entered this function. It might have changed already.
1972  * But if it has, we will receive (or have already received and
1973  * queued) another signal and come here again.
1974  *
1975  * We are not holding NotifyQueueLock here! The queue can only
1976  * extend beyond the head pointer (see above) and we leave our
1977  * backend's pointer where it is so nobody will truncate or
1978  * rewrite pages under us. Especially we don't want to hold a lock
1979  * while sending the notifications to the frontend.
1980  */
1981  reachedStop = asyncQueueProcessPageEntries(&pos, head,
1982  page_buffer.buf,
1983  snapshot);
1984  } while (!reachedStop);
1985  }
1986  PG_FINALLY();
1987  {
1988  /* Update shared state */
1989  LWLockAcquire(NotifyQueueLock, LW_SHARED);
1991  LWLockRelease(NotifyQueueLock);
1992  }
1993  PG_END_TRY();
1994 
1995  /* Done with snapshot */
1996  UnregisterSnapshot(snapshot);
1997 }
1998 
1999 /*
2000  * Fetch notifications from the shared queue, beginning at position current,
2001  * and deliver relevant ones to my frontend.
2002  *
2003  * The current page must have been fetched into page_buffer from shared
2004  * memory. (We could access the page right in shared memory, but that
2005  * would imply holding the SLRU bank lock throughout this routine.)
2006  *
2007  * We stop if we reach the "stop" position, or reach a notification from an
2008  * uncommitted transaction, or reach the end of the page.
2009  *
2010  * The function returns true once we have reached the stop position or an
2011  * uncommitted notification, and false if we have finished with the page.
2012  * In other words: once it returns true there is no need to look further.
2013  * The QueuePosition *current is advanced past all processed messages.
2014  */
2015 static bool
2017  QueuePosition stop,
2018  char *page_buffer,
2019  Snapshot snapshot)
2020 {
2021  bool reachedStop = false;
2022  bool reachedEndOfPage;
2023  AsyncQueueEntry *qe;
2024 
2025  do
2026  {
2027  QueuePosition thisentry = *current;
2028 
2029  if (QUEUE_POS_EQUAL(thisentry, stop))
2030  break;
2031 
2032  qe = (AsyncQueueEntry *) (page_buffer + QUEUE_POS_OFFSET(thisentry));
2033 
2034  /*
2035  * Advance *current over this message, possibly to the next page. As
2036  * noted in the comments for asyncQueueReadAllNotifications, we must
2037  * do this before possibly failing while processing the message.
2038  */
2039  reachedEndOfPage = asyncQueueAdvance(current, qe->length);
2040 
2041  /* Ignore messages destined for other databases */
2042  if (qe->dboid == MyDatabaseId)
2043  {
2044  if (XidInMVCCSnapshot(qe->xid, snapshot))
2045  {
2046  /*
2047  * The source transaction is still in progress, so we can't
2048  * process this message yet. Break out of the loop, but first
2049  * back up *current so we will reprocess the message next
2050  * time. (Note: it is unlikely but not impossible for
2051  * TransactionIdDidCommit to fail, so we can't really avoid
2052  * this advance-then-back-up behavior when dealing with an
2053  * uncommitted message.)
2054  *
2055  * Note that we must test XidInMVCCSnapshot before we test
2056  * TransactionIdDidCommit, else we might return a message from
2057  * a transaction that is not yet visible to snapshots; compare
2058  * the comments at the head of heapam_visibility.c.
2059  *
2060  * Also, while our own xact won't be listed in the snapshot,
2061  * we need not check for TransactionIdIsCurrentTransactionId
2062  * because our transaction cannot (yet) have queued any
2063  * messages.
2064  */
2065  *current = thisentry;
2066  reachedStop = true;
2067  break;
2068  }
2069  else if (TransactionIdDidCommit(qe->xid))
2070  {
2071  /* qe->data is the null-terminated channel name */
2072  char *channel = qe->data;
2073 
2074  if (IsListeningOn(channel))
2075  {
2076  /* payload follows channel name */
2077  char *payload = qe->data + strlen(channel) + 1;
2078 
2079  NotifyMyFrontEnd(channel, payload, qe->srcPid);
2080  }
2081  }
2082  else
2083  {
2084  /*
2085  * The source transaction aborted or crashed, so we just
2086  * ignore its notifications.
2087  */
2088  }
2089  }
2090 
2091  /* Loop back if we're not at end of page */
2092  } while (!reachedEndOfPage);
2093 
2094  if (QUEUE_POS_EQUAL(*current, stop))
2095  reachedStop = true;
2096 
2097  return reachedStop;
2098 }
2099 
2100 /*
2101  * Advance the shared queue tail variable to the minimum of all the
2102  * per-backend tail pointers. Truncate pg_notify space if possible.
2103  *
2104  * This is (usually) called during CommitTransaction(), so it's important for
2105  * it to have very low probability of failure.
2106  */
2107 static void
2109 {
2110  QueuePosition min;
2111  int64 oldtailpage;
2112  int64 newtailpage;
2113  int64 boundary;
2114 
2115  /* Restrict task to one backend per cluster; see SimpleLruTruncate(). */
2116  LWLockAcquire(NotifyQueueTailLock, LW_EXCLUSIVE);
2117 
2118  /*
2119  * Compute the new tail. Pre-v13, it's essential that QUEUE_TAIL be exact
2120  * (ie, exactly match at least one backend's queue position), so it must
2121  * be updated atomically with the actual computation. Since v13, we could
2122  * get away with not doing it like that, but it seems prudent to keep it
2123  * so.
2124  *
2125  * Also, because incoming backends will scan forward from QUEUE_TAIL, that
2126  * must be advanced before we can truncate any data. Thus, QUEUE_TAIL is
2127  * the logical tail, while QUEUE_STOP_PAGE is the physical tail, or oldest
2128  * un-truncated page. When QUEUE_STOP_PAGE != QUEUE_POS_PAGE(QUEUE_TAIL),
2129  * there are pages we can truncate but haven't yet finished doing so.
2130  *
2131  * For concurrency's sake, we don't want to hold NotifyQueueLock while
2132  * performing SimpleLruTruncate. This is OK because no backend will try
2133  * to access the pages we are in the midst of truncating.
2134  */
2135  LWLockAcquire(NotifyQueueLock, LW_EXCLUSIVE);
2136  min = QUEUE_HEAD;
2138  {
2140  min = QUEUE_POS_MIN(min, QUEUE_BACKEND_POS(i));
2141  }
2142  QUEUE_TAIL = min;
2143  oldtailpage = QUEUE_STOP_PAGE;
2144  LWLockRelease(NotifyQueueLock);
2145 
2146  /*
2147  * We can truncate something if the global tail advanced across an SLRU
2148  * segment boundary.
2149  *
2150  * XXX it might be better to truncate only once every several segments, to
2151  * reduce the number of directory scans.
2152  */
2153  newtailpage = QUEUE_POS_PAGE(min);
2154  boundary = newtailpage - (newtailpage % SLRU_PAGES_PER_SEGMENT);
2155  if (asyncQueuePagePrecedes(oldtailpage, boundary))
2156  {
2157  /*
2158  * SimpleLruTruncate() will ask for SLRU bank locks but will also
2159  * release the lock again.
2160  */
2161  SimpleLruTruncate(NotifyCtl, newtailpage);
2162 
2163  LWLockAcquire(NotifyQueueLock, LW_EXCLUSIVE);
2164  QUEUE_STOP_PAGE = newtailpage;
2165  LWLockRelease(NotifyQueueLock);
2166  }
2167 
2168  LWLockRelease(NotifyQueueTailLock);
2169 }
2170 
2171 /*
2172  * ProcessIncomingNotify
2173  *
2174  * Scan the queue for arriving notifications and report them to the front
2175  * end. The notifications might be from other sessions, or our own;
2176  * there's no need to distinguish here.
2177  *
2178  * If "flush" is true, force any frontend messages out immediately.
2179  *
2180  * NOTE: since we are outside any transaction, we must create our own.
2181  */
2182 static void
2184 {
2185  /* We *must* reset the flag */
2186  notifyInterruptPending = false;
2187 
2188  /* Do nothing else if we aren't actively listening */
2189  if (listenChannels == NIL)
2190  return;
2191 
2192  if (Trace_notify)
2193  elog(DEBUG1, "ProcessIncomingNotify");
2194 
2195  set_ps_display("notify interrupt");
2196 
2197  /*
2198  * We must run asyncQueueReadAllNotifications inside a transaction, else
2199  * bad things happen if it gets an error.
2200  */
2202 
2204 
2206 
2207  /*
2208  * If this isn't an end-of-command case, we must flush the notify messages
2209  * to ensure frontend gets them promptly.
2210  */
2211  if (flush)
2212  pq_flush();
2213 
2214  set_ps_display("idle");
2215 
2216  if (Trace_notify)
2217  elog(DEBUG1, "ProcessIncomingNotify: done");
2218 }
2219 
2220 /*
2221  * Send NOTIFY message to my front end.
2222  */
2223 void
2224 NotifyMyFrontEnd(const char *channel, const char *payload, int32 srcPid)
2225 {
2227  {
2229 
2231  pq_sendint32(&buf, srcPid);
2232  pq_sendstring(&buf, channel);
2233  pq_sendstring(&buf, payload);
2234  pq_endmessage(&buf);
2235 
2236  /*
2237  * NOTE: we do not do pq_flush() here. Some level of caller will
2238  * handle it later, allowing this message to be combined into a packet
2239  * with other ones.
2240  */
2241  }
2242  else
2243  elog(INFO, "NOTIFY for \"%s\" payload \"%s\"", channel, payload);
2244 }
2245 
2246 /* Does pendingNotifies include a match for the given event? */
2247 static bool
2249 {
2250  if (pendingNotifies == NULL)
2251  return false;
2252 
2253  if (pendingNotifies->hashtab != NULL)
2254  {
2255  /* Use the hash table to probe for a match */
2257  &n,
2258  HASH_FIND,
2259  NULL))
2260  return true;
2261  }
2262  else
2263  {
2264  /* Must scan the event list */
2265  ListCell *l;
2266 
2267  foreach(l, pendingNotifies->events)
2268  {
2269  Notification *oldn = (Notification *) lfirst(l);
2270 
2271  if (n->channel_len == oldn->channel_len &&
2272  n->payload_len == oldn->payload_len &&
2273  memcmp(n->data, oldn->data,
2274  n->channel_len + n->payload_len + 2) == 0)
2275  return true;
2276  }
2277  }
2278 
2279  return false;
2280 }
2281 
2282 /*
2283  * Add a notification event to a pre-existing pendingNotifies list.
2284  *
2285  * Because pendingNotifies->events is already nonempty, this works
2286  * correctly no matter what CurrentMemoryContext is.
2287  */
2288 static void
2290 {
2292 
2293  /* Create the hash table if it's time to */
2295  pendingNotifies->hashtab == NULL)
2296  {
2297  HASHCTL hash_ctl;
2298  ListCell *l;
2299 
2300  /* Create the hash table */
2301  hash_ctl.keysize = sizeof(Notification *);
2302  hash_ctl.entrysize = sizeof(struct NotificationHash);
2303  hash_ctl.hash = notification_hash;
2304  hash_ctl.match = notification_match;
2305  hash_ctl.hcxt = CurTransactionContext;
2307  hash_create("Pending Notifies",
2308  256L,
2309  &hash_ctl,
2311 
2312  /* Insert all the already-existing events */
2313  foreach(l, pendingNotifies->events)
2314  {
2315  Notification *oldn = (Notification *) lfirst(l);
2316  bool found;
2317 
2319  &oldn,
2320  HASH_ENTER,
2321  &found);
2322  Assert(!found);
2323  }
2324  }
2325 
2326  /* Add new event to the list, in order */
2328 
2329  /* Add event to the hash table if needed */
2330  if (pendingNotifies->hashtab != NULL)
2331  {
2332  bool found;
2333 
2335  &n,
2336  HASH_ENTER,
2337  &found);
2338  Assert(!found);
2339  }
2340 }
2341 
2342 /*
2343  * notification_hash: hash function for notification hash table
2344  *
2345  * The hash "keys" are pointers to Notification structs.
2346  */
2347 static uint32
2348 notification_hash(const void *key, Size keysize)
2349 {
2350  const Notification *k = *(const Notification *const *) key;
2351 
2352  Assert(keysize == sizeof(Notification *));
2353  /* We don't bother to include the payload's trailing null in the hash */
2354  return DatumGetUInt32(hash_any((const unsigned char *) k->data,
2355  k->channel_len + k->payload_len + 1));
2356 }
2357 
2358 /*
2359  * notification_match: match function to use with notification_hash
2360  */
2361 static int
2362 notification_match(const void *key1, const void *key2, Size keysize)
2363 {
2364  const Notification *k1 = *(const Notification *const *) key1;
2365  const Notification *k2 = *(const Notification *const *) key2;
2366 
2367  Assert(keysize == sizeof(Notification *));
2368  if (k1->channel_len == k2->channel_len &&
2369  k1->payload_len == k2->payload_len &&
2370  memcmp(k1->data, k2->data,
2371  k1->channel_len + k1->payload_len + 2) == 0)
2372  return 0; /* equal */
2373  return 1; /* not equal */
2374 }
2375 
2376 /* Clear the pendingActions and pendingNotifies lists. */
2377 static void
2379 {
2380  /*
2381  * Everything's allocated in either TopTransactionContext or the context
2382  * for the subtransaction to which it corresponds. So, there's nothing to
2383  * do here except reset the pointers; the space will be reclaimed when the
2384  * contexts are deleted.
2385  */
2386  pendingActions = NULL;
2387  pendingNotifies = NULL;
2388 }
2389 
2390 /*
2391  * GUC check_hook for notify_buffers
2392  */
2393 bool
2395 {
2396  return check_slru_buffers("notify_buffers", newval);
2397 }
static void SignalBackends(void)
Definition: async.c:1581
static double asyncQueueUsage(void)
Definition: async.c:1506
#define MIN_HASHABLE_NOTIFIES
Definition: async.c:397
static void Exec_ListenCommit(const char *channel)
Definition: async.c:1136
static void asyncQueueNotificationToEntry(Notification *n, AsyncQueueEntry *qe)
Definition: async.c:1320
#define QUEUE_FIRST_LISTENER
Definition: async.c:299
#define QUEUE_POS_MAX(x, y)
Definition: async.c:222
static bool tryAdvanceTail
Definition: async.c:422
struct QueuePosition QueuePosition
void HandleNotifyInterrupt(void)
Definition: async.c:1804
static void Exec_UnlistenCommit(const char *channel)
Definition: async.c:1163
static void asyncQueueAdvanceTail(void)
Definition: async.c:2108
int max_notify_queue_pages
Definition: async.c:428
static void Exec_ListenPreCommit(void)
Definition: async.c:1041
static ActionList * pendingActions
Definition: async.c:352
static uint32 notification_hash(const void *key, Size keysize)
Definition: async.c:2348
void Async_UnlistenAll(void)
Definition: async.c:770
static SlruCtlData NotifyCtlData
Definition: async.c:308
void NotifyMyFrontEnd(const char *channel, const char *payload, int32 srcPid)
Definition: async.c:2224
void AtCommit_Notify(void)
Definition: async.c:968
#define QUEUE_POS_MIN(x, y)
Definition: async.c:216
void ProcessNotifyInterrupt(bool flush)
Definition: async.c:1834
ListenActionKind
Definition: async.c:333
@ LISTEN_LISTEN
Definition: async.c:334
@ LISTEN_UNLISTEN_ALL
Definition: async.c:336
@ LISTEN_UNLISTEN
Definition: async.c:335
static bool AsyncExistsPendingNotify(Notification *n)
Definition: async.c:2248
#define QUEUE_BACKEND_POS(i)
Definition: async.c:303
static bool asyncQueueProcessPageEntries(volatile QueuePosition *current, QueuePosition stop, char *page_buffer, Snapshot snapshot)
Definition: async.c:2016
static int notification_match(const void *key1, const void *key2, Size keysize)
Definition: async.c:2362
#define SET_QUEUE_POS(x, y, z)
Definition: async.c:203
static void ProcessIncomingNotify(bool flush)
Definition: async.c:2183
static void asyncQueueReadAllNotifications(void)
Definition: async.c:1851
static void Async_UnlistenOnExit(int code, Datum arg)
Definition: async.c:823
#define QUEUE_POS_OFFSET(x)
Definition: async.c:201
bool Trace_notify
Definition: async.c:425
static ListCell * asyncQueueAddEntries(ListCell *nextNotify)
Definition: async.c:1356
static void ClearPendingActionsAndNotifies(void)
Definition: async.c:2378
static List * listenChannels
Definition: async.c:320
Datum pg_listening_channels(PG_FUNCTION_ARGS)
Definition: async.c:790
Datum pg_notify(PG_FUNCTION_ARGS)
Definition: async.c:557
static NotificationList * pendingNotifies
Definition: async.c:404
#define AsyncQueueEntryEmptySize
Definition: async.c:189
static void AddEventToPendingNotifies(Notification *n)
Definition: async.c:2289
static AsyncQueueControl * asyncQueueControl
Definition: async.c:294
static bool unlistenExitRegistered
Definition: async.c:416
static bool asyncQueuePagePrecedes(int64 p, int64 q)
Definition: async.c:476
static bool asyncQueueAdvance(volatile QueuePosition *position, int entryLength)
Definition: async.c:1287
#define QUEUE_TAIL
Definition: async.c:297
void AtAbort_Notify(void)
Definition: async.c:1671
#define QUEUE_POS_PAGE(x)
Definition: async.c:200
void PreCommit_Notify(void)
Definition: async.c:861
#define QUEUE_CLEANUP_DELAY
Definition: async.c:238
struct AsyncQueueControl AsyncQueueControl
static void asyncQueueFillWarning(void)
Definition: async.c:1527
#define QUEUE_BACKEND_PID(i)
Definition: async.c:300
static void Exec_UnlistenAllCommit(void)
Definition: async.c:1194
struct ActionList ActionList
Size AsyncShmemSize(void)
Definition: async.c:485
#define QUEUE_FULL_WARN_INTERVAL
Definition: async.c:313
void Async_Unlisten(const char *channel)
Definition: async.c:752
void Async_Listen(const char *channel)
Definition: async.c:738
#define NOTIFY_PAYLOAD_MAX_LENGTH
Definition: async.c:163
#define QUEUE_POS_IS_ZERO(x)
Definition: async.c:212
#define NotifyCtl
Definition: async.c:310
static int64 asyncQueuePageDiff(int64 p, int64 q)
Definition: async.c:466
static void queue_listen(ListenActionKind action, const char *channel)
Definition: async.c:690
#define QUEUEALIGN(len)
Definition: async.c:187
static bool amRegisteredListener
Definition: async.c:419
#define QUEUE_NEXT_LISTENER(i)
Definition: async.c:302
#define QUEUE_BACKEND_DBOID(i)
Definition: async.c:301
void AtSubAbort_Notify(void)
Definition: async.c:1761
struct NotificationList NotificationList
void AtPrepare_Notify(void)
Definition: async.c:836
#define QUEUE_PAGESIZE
Definition: async.c:311
void AtSubCommit_Notify(void)
Definition: async.c:1691
static bool asyncQueueIsFull(void)
Definition: async.c:1272
#define QUEUE_HEAD
Definition: async.c:296
void AsyncShmemInit(void)
Definition: async.c:502
static void asyncQueueUnregister(void)
Definition: async.c:1231
Datum pg_notification_queue_usage(PG_FUNCTION_ARGS)
Definition: async.c:1481
struct AsyncQueueEntry AsyncQueueEntry
#define QUEUE_POS_EQUAL(x, y)
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struct Notification Notification
static bool IsListeningOn(const char *channel)
Definition: async.c:1212
void Async_Notify(const char *channel, const char *payload)
Definition: async.c:591
volatile sig_atomic_t notifyInterruptPending
Definition: async.c:413
bool check_notify_buffers(int *newval, void **extra, GucSource source)
Definition: async.c:2394
struct QueueBackendStatus QueueBackendStatus
#define QUEUE_STOP_PAGE
Definition: async.c:298
bool TimestampDifferenceExceeds(TimestampTz start_time, TimestampTz stop_time, int msec)
Definition: timestamp.c:1780
TimestampTz GetCurrentTimestamp(void)
Definition: timestamp.c:1644
#define CStringGetTextDatum(s)
Definition: builtins.h:97
#define Assert(condition)
Definition: c.h:812
int64_t int64
Definition: c.h:482
#define FLEXIBLE_ARRAY_MEMBER
Definition: c.h:417
int32_t int32
Definition: c.h:481
uint16_t uint16
Definition: c.h:484
uint32_t uint32
Definition: c.h:485
uint32 TransactionId
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size_t Size
Definition: c.h:559
int64 TimestampTz
Definition: timestamp.h:39
@ DestRemote
Definition: dest.h:89
void * hash_search(HTAB *hashp, const void *keyPtr, HASHACTION action, bool *foundPtr)
Definition: dynahash.c:955
HTAB * hash_create(const char *tabname, long nelem, const HASHCTL *info, int flags)
Definition: dynahash.c:352
int errdetail(const char *fmt,...)
Definition: elog.c:1203
int errhint(const char *fmt,...)
Definition: elog.c:1317
int errcode(int sqlerrcode)
Definition: elog.c:853
int errmsg(const char *fmt,...)
Definition: elog.c:1070
#define DEBUG3
Definition: elog.h:28
#define PG_TRY(...)
Definition: elog.h:371
#define WARNING
Definition: elog.h:36
#define PG_END_TRY(...)
Definition: elog.h:396
#define DEBUG1
Definition: elog.h:30
#define ERROR
Definition: elog.h:39
#define elog(elevel,...)
Definition: elog.h:225
#define PG_FINALLY(...)
Definition: elog.h:388
#define INFO
Definition: elog.h:34
#define ereport(elevel,...)
Definition: elog.h:149
#define PG_RETURN_VOID()
Definition: fmgr.h:349
#define PG_GETARG_TEXT_PP(n)
Definition: fmgr.h:309
#define PG_RETURN_FLOAT8(x)
Definition: fmgr.h:367
#define PG_ARGISNULL(n)
Definition: fmgr.h:209
#define PG_FUNCTION_ARGS
Definition: fmgr.h:193
#define SRF_IS_FIRSTCALL()
Definition: funcapi.h:304
#define SRF_PERCALL_SETUP()
Definition: funcapi.h:308
#define SRF_RETURN_NEXT(_funcctx, _result)
Definition: funcapi.h:310
#define SRF_FIRSTCALL_INIT()
Definition: funcapi.h:306
#define SRF_RETURN_DONE(_funcctx)
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int MyProcPid
Definition: globals.c:46
ProcNumber MyProcNumber
Definition: globals.c:89
int MaxBackends
Definition: globals.c:145
int notify_buffers
Definition: globals.c:163
struct Latch * MyLatch
Definition: globals.c:62
Oid MyDatabaseId
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#define newval
GucSource
Definition: guc.h:108
static Datum hash_any(const unsigned char *k, int keylen)
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@ HASH_FIND
Definition: hsearch.h:113
@ HASH_ENTER
Definition: hsearch.h:114
#define HASH_CONTEXT
Definition: hsearch.h:102
#define HASH_ELEM
Definition: hsearch.h:95
#define HASH_COMPARE
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#define HASH_FUNCTION
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#define IsParallelWorker()
Definition: parallel.h:60
void before_shmem_exit(pg_on_exit_callback function, Datum arg)
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int i
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void SetLatch(Latch *latch)
Definition: latch.c:632
#define pq_flush()
Definition: libpq.h:46
List * lappend(List *list, void *datum)
Definition: list.c:339
List * list_concat(List *list1, const List *list2)
Definition: list.c:561
void list_free_deep(List *list)
Definition: list.c:1560
void LockSharedObject(Oid classid, Oid objid, uint16 objsubid, LOCKMODE lockmode)
Definition: lmgr.c:1072
#define AccessExclusiveLock
Definition: lockdefs.h:43
bool LWLockAcquire(LWLock *lock, LWLockMode mode)
Definition: lwlock.c:1168
void LWLockRelease(LWLock *lock)
Definition: lwlock.c:1781
@ LWTRANCHE_NOTIFY_SLRU
Definition: lwlock.h:213
@ LWTRANCHE_NOTIFY_BUFFER
Definition: lwlock.h:184
@ LW_SHARED
Definition: lwlock.h:115
@ LW_EXCLUSIVE
Definition: lwlock.h:114
MemoryContext TopTransactionContext
Definition: mcxt.c:154
char * pstrdup(const char *in)
Definition: mcxt.c:1696
void pfree(void *pointer)
Definition: mcxt.c:1521
MemoryContext TopMemoryContext
Definition: mcxt.c:149
MemoryContext CurTransactionContext
Definition: mcxt.c:155
void * MemoryContextAlloc(MemoryContext context, Size size)
Definition: mcxt.c:1181
void * palloc(Size size)
Definition: mcxt.c:1317
#define InvalidPid
Definition: miscadmin.h:32
void * arg
#define NAMEDATALEN
const void * data
#define lfirst(lc)
Definition: pg_list.h:172
static int list_length(const List *l)
Definition: pg_list.h:152
#define NIL
Definition: pg_list.h:68
#define foreach_delete_current(lst, var_or_cell)
Definition: pg_list.h:391
#define list_make1(x1)
Definition: pg_list.h:212
static ListCell * list_head(const List *l)
Definition: pg_list.h:128
static void * list_nth(const List *list, int n)
Definition: pg_list.h:299
static ListCell * lnext(const List *l, const ListCell *c)
Definition: pg_list.h:343
static rewind_source * source
Definition: pg_rewind.c:89
static char * buf
Definition: pg_test_fsync.c:72
CommandDest whereToSendOutput
Definition: postgres.c:90
static uint32 DatumGetUInt32(Datum X)
Definition: postgres.h:222
uintptr_t Datum
Definition: postgres.h:64
#define InvalidOid
Definition: postgres_ext.h:36
unsigned int Oid
Definition: postgres_ext.h:31
void pq_sendstring(StringInfo buf, const char *str)
Definition: pqformat.c:195
void pq_endmessage(StringInfo buf)
Definition: pqformat.c:296
void pq_beginmessage(StringInfo buf, char msgtype)
Definition: pqformat.c:88
static void pq_sendint32(StringInfo buf, uint32 i)
Definition: pqformat.h:144
#define INVALID_PROC_NUMBER
Definition: procnumber.h:26
int ProcNumber
Definition: procnumber.h:24
int SendProcSignal(pid_t pid, ProcSignalReason reason, ProcNumber procNumber)
Definition: procsignal.c:281
@ PROCSIG_NOTIFY_INTERRUPT
Definition: procsignal.h:33
#define PqMsg_NotificationResponse
Definition: protocol.h:41
static void set_ps_display(const char *activity)
Definition: ps_status.h:40
MemoryContextSwitchTo(old_ctx)
Size add_size(Size s1, Size s2)
Definition: shmem.c:488
void * ShmemInitStruct(const char *name, Size size, bool *foundPtr)
Definition: shmem.c:382
Size mul_size(Size s1, Size s2)
Definition: shmem.c:505
static pg_noinline void Size size
Definition: slab.c:607
void SimpleLruInit(SlruCtl ctl, const char *name, int nslots, int nlsns, const char *subdir, int buffer_tranche_id, int bank_tranche_id, SyncRequestHandler sync_handler, bool long_segment_names)
Definition: slru.c:252
int SimpleLruReadPage_ReadOnly(SlruCtl ctl, int64 pageno, TransactionId xid)
Definition: slru.c:605
bool SlruScanDirectory(SlruCtl ctl, SlruScanCallback callback, void *data)
Definition: slru.c:1791
bool SlruScanDirCbDeleteAll(SlruCtl ctl, char *filename, int64 segpage, void *data)
Definition: slru.c:1744
int SimpleLruReadPage(SlruCtl ctl, int64 pageno, bool write_ok, TransactionId xid)
Definition: slru.c:502
int SimpleLruZeroPage(SlruCtl ctl, int64 pageno)
Definition: slru.c:375
void SimpleLruTruncate(SlruCtl ctl, int64 cutoffPage)
Definition: slru.c:1408
Size SimpleLruShmemSize(int nslots, int nlsns)
Definition: slru.c:199
bool check_slru_buffers(const char *name, int *newval)
Definition: slru.c:355
static LWLock * SimpleLruGetBankLock(SlruCtl ctl, int64 pageno)
Definition: slru.h:178
#define SLRU_PAGES_PER_SEGMENT
Definition: slru.h:39
bool XidInMVCCSnapshot(TransactionId xid, Snapshot snapshot)
Definition: snapmgr.c:1804
Snapshot GetLatestSnapshot(void)
Definition: snapmgr.c:287
void UnregisterSnapshot(Snapshot snapshot)
Definition: snapmgr.c:798
Snapshot RegisterSnapshot(Snapshot snapshot)
Definition: snapmgr.c:756
List * actions
Definition: async.c:348
int nestingLevel
Definition: async.c:347
struct ActionList * upper
Definition: async.c:349
ProcNumber firstListener
Definition: async.c:288
int64 stopPage
Definition: async.c:286
QueuePosition tail
Definition: async.c:284
QueuePosition head
Definition: async.c:283
QueueBackendStatus backend[FLEXIBLE_ARRAY_MEMBER]
Definition: async.c:291
TimestampTz lastQueueFillWarn
Definition: async.c:290
int32 srcPid
Definition: async.c:182
char data[NAMEDATALEN+NOTIFY_PAYLOAD_MAX_LENGTH]
Definition: async.c:183
TransactionId xid
Definition: async.c:181
uint64 call_cntr
Definition: funcapi.h:65
Size keysize
Definition: hsearch.h:75
HashValueFunc hash
Definition: hsearch.h:78
Size entrysize
Definition: hsearch.h:76
HashCompareFunc match
Definition: hsearch.h:80
MemoryContext hcxt
Definition: hsearch.h:86
Definition: dynahash.c:220
Definition: lwlock.h:42
Definition: pg_list.h:54
char channel[FLEXIBLE_ARRAY_MEMBER]
Definition: async.c:342
ListenActionKind action
Definition: async.c:341
Notification * event
Definition: async.c:401
int nestingLevel
Definition: async.c:391
HTAB * hashtab
Definition: async.c:393
List * events
Definition: async.c:392
struct NotificationList * upper
Definition: async.c:394
uint16 payload_len
Definition: async.c:384
char data[FLEXIBLE_ARRAY_MEMBER]
Definition: async.c:386
uint16 channel_len
Definition: async.c:383
ProcNumber nextListener
Definition: async.c:247
QueuePosition pos
Definition: async.c:248
int offset
Definition: async.c:197
int64 page
Definition: async.c:196
@ SYNC_HANDLER_NONE
Definition: sync.h:42
bool TransactionIdDidCommit(TransactionId transactionId)
Definition: transam.c:126
#define InvalidTransactionId
Definition: transam.h:31
void PreventCommandDuringRecovery(const char *cmdname)
Definition: utility.c:441
static void usage(const char *progname)
Definition: vacuumlo.c:414
char * text_to_cstring(const text *t)
Definition: varlena.c:217
bool IsTransactionOrTransactionBlock(void)
Definition: xact.c:4981
int GetCurrentTransactionNestLevel(void)
Definition: xact.c:928
void StartTransactionCommand(void)
Definition: xact.c:3051
void CommitTransactionCommand(void)
Definition: xact.c:3149
TransactionId GetCurrentTransactionId(void)
Definition: xact.c:453